Volume 246, 2023

Evolution of the electrical double layer with electrolyte concentration probed by second harmonic scattering

Abstract

Investigating the electrical double layer (EDL) structure has been a long-standing challenge and has seen the emergence of several sophisticated techniques able to probe selectively the few molecular layers of a solid/water interface. While a qualitative estimation of the thickness of the EDL can be obtained using simple theoretical models, following experimentally its evolution is not straightforward and can be even more complicated in nano- or microscale systems, particularly when changing the ionic concentration by several orders of magnitude. Here, we bring insight into the structure of the EDL of SiO2 nanoparticle suspensions and its evolution with increasing ionic concentration using angle-resolved second harmonic scattering (AR-SHS). Below millimolar salt concentrations, we can successively characterize inner-sphere adsorption, diffuse layer formation, and outer-sphere adsorption. Moreover, we show for the first time that, by appropriately selecting the nanoparticle size, it is possible to retrieve information also in the millimolar range. There, we observe a decrease in the magnitude of the surface potential corresponding to a compression in the EDL thickness, which agrees with the results of several other electroanalytical and optical techniques. Molecular dynamics simulations suggest that the EDL compression mainly results from the diffuse layer compression rather than outer-sphere ions (Stern plane) moving closer to the surface.

Graphical abstract: Evolution of the electrical double layer with electrolyte concentration probed by second harmonic scattering

Associated articles

Supplementary files

Article information

Article type
Paper
Submitted
13 fev 2023
Accepted
22 fev 2023
First published
17 iyl 2023
This article is Open Access
Creative Commons BY license

Faraday Discuss., 2023,246, 407-425

Evolution of the electrical double layer with electrolyte concentration probed by second harmonic scattering

B. Chu, D. Biriukov, M. Bischoff, M. Předota, S. Roke and A. Marchioro, Faraday Discuss., 2023, 246, 407 DOI: 10.1039/D3FD00036B

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